Electric-field-driven resistive transition in multiferroic SrCo2Fe16O27/Sr3Co2Fe24O41composite

Abstract

We report observation of electric-field-driven resistive transition at a characteristic threshold field Eth(T) across a temperature range 10-200 K in an off-stoichiometric composite of (~80 vol%) W- and (~20 vol%) Z-type hexaferrites. The dielectric constant ε and the relaxation time constant τ too exhibit anomalous jump at Eth(T). The Eth(T), the extent of jump in resistivity (), and the hysteresis associated with the jump [ Eth(T)] are found to decrease systematically with the increase in temperature (T). Several temperature-driven phase transitions have also been noticed in low and high resistive states (LRS and HRS). The temperature-driven conduction turns out to be governed by activated hopping of small polarons at all the phases with electric (E) and magnetic (H) field dependent activation energy U(E,H). Interestingly, as the temperature is raised, the E-driven conduction at a fixed temperature evolves from Ohmic to non-Ohmic across 10-200 K and within 110-200 K, follows three-dimensional variable range hopping (3D-VRH) with stretched exponential exp[(E0/E)4] or power law (E0/E)m (m varies within 0.6-0.7 and 0.6-0.8 at LRS and HRS, respectively) dependence depending on the localization length (ζE) to diffusion length (dE) ratio associated with E-driven conduction. The (E,T) follows universal scaling only at LRS within 10-110 K but not at higher temperature or at HRS. The entire set of observations has been discussed within the framework of structural evolution of the point-defect (cation vacancies or oxygen excess) network. This comprehensive map of esoteric -E-T-H and ε-E-T-H patterns provides insights on defect driven effects in a composite useful for tuning both the resistive transition and multiferroicity.

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